Throw able robot with improved drive system

ABSTRACT

A two wheeled throwable robot comprises an elongate chassis with two ends, a motor at each end, drive wheels connected to the motors, and a tail extending from the elongate chassis. The throwable robot includes a pair of torque limiting mechanisms, each torque limiting mechanism being operatively coupled between a motor and a drive wheel. Each torque limiting mechanism comprises a drive flange portion, a driven flange portion and a plurality of rollers. A spring element provides a ring force that biases the rollers toward the driven flange portion.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is a continuation of U.S. patent application Ser. No. 15/998,686 filed Aug. 15, 2018, now U.S. Pat. No. 10,589,430, which claims the benefit of U.S. Provisional Application No. 62/545,849, filed Aug. 15, 2017, and also claims the benefit of U.S. Provisional Application No. 62/545,879, filed Aug. 15, 2017, all of the above applications are incorporated herein in their entirety by reference.

BACKGROUND OF THE INVENTION

Throwable robots used in military and policing operations need to be robust and able to survive exposure to rugged conditions including water and vertical drops. Improvements in reliability and performance for robots used in high stakes military and police operations are desirable.

SUMMARY OF THE INVENTION

This invention relates to a means to readily, reliably, and securely enable or disable a device, for example a throwable robot. In embodiments, the throwable surveillance robot comprises a pair of axially aligned drive wheels, each wheel having a maximum diameter. The surveillance robot may have a body comprising a housing extending between the drive wheels. In embodiments, the housing is disposed completely within a cylinder defined by the maximum diameters of the drive wheels. In embodiments, the housing defines a housing cavity containing a receiver, a transmitter and a video camera connected to the transmitter. The housing may include a key holding portion defining a key holding slot having a key insertion and withdrawal axis. In embodiments, throwing of the surveillance robot is facilitated by a design providing a total weight of less than six pounds. The pair of axially aligned drive wheels a starboard drive wheel and a port drive wheel.

In embodiments, the surveillance robot comprises a pair of motors disposed inside the housing cavity defined by the housing. In embodiments, the pair of motors comprises a starboard motor and a port motor, each motor comprising a motor shaft. A starboard motor gear may be fixed to the motor shaft of the starboard motor. The starboard motor gear may comprise a plurality of gear teeth configured to mate with the toothed outer portion of a starboard drive member. In embodiments, the starboard drive member comprises a starboard driving flange portion and the toothed outer portion. In embodiments, the starboard driving flange portion defines a plurality apertures. The apertures may be arranged in a radial pattern extending along a circular path. In embodiments, the starboard driving flange portion of the starboard drive member defines a central opening.

In embodiments, the surveillance robot comprises a starboard driven member comprising a mating shaft portion that extends through the central opening defined by the starboard drive member. In embodiments, the driven member is positioned so that a driven flange portion of the driven member is disposed opposite the driving flange of the starboard drive member. In embodiments, the starboard driven flange portion defines a plurality of holes, each hole being dimensioned and positioned to temporarily or permanently receive a portion of one of the plurality of rollers. In embodiments, each hole is dimensioned and configured such that one of the plurality of rollers cannot pass through the hole. In some embodiments, each hole comprises a through hole. In other embodiments, each hole comprises a blind hole. In some embodiments, the rollers comprise a plurality of cylindrical rods. In other embodiments, the rollers comprise a plurality of spherical balls.

The surveillance robot may also comprise a starboard spring element that provides a spring force. In embodiments, the spring force provided by the starboard spring element acts to bias each of the rollers toward the starboard driven flange of the starboard driven member. In embodiments, the starboard spring element comprises a wave spring. Wave springs that may be suitable in some applications are disclosed in the following patents, all of which are hereby incorporated by reference: U.S. Pat. Nos. 7,793,923, 6,758,465, 6,669,184, 6,598,406, 6,408,631, 6,068,250, and 5,558,393.

In embodiments, the surveillance robot comprises a pair of motors disposed inside the housing cavity defined by the housing. In embodiments, the pair of motors comprises a port motor and a port motor, each motor comprising a motor shaft. A port motor gear may be fixed to the motor shaft of the port motor. The port motor gear may comprise a plurality of gear teeth configured to mate with the toothed outer portion of a port drive member. In embodiments, the port drive member comprises a port driving flange portion and the toothed outer portion. In embodiments, the port driving flange portion defines a plurality apertures. The apertures may be arranged in a radial pattern extending along a circular path. In embodiments, the port driving flange portion of the port drive member defines a central opening.

In embodiments, the surveillance robot comprises a port driven member comprising a mating shaft portion that extends through the central opening defined by the port drive member. In embodiments, the driven member is positioned so that a driven flange portion of the driven member is disposed opposite the driving flange of the port drive member. In embodiments, the port driven flange portion defines a plurality of holes, each hole being dimensioned and positioned to temporarily or permanently receive a portion of one of the plurality of rollers. In embodiments, each hole is dimensioned and configured such that one of the plurality of rollers cannot pass through the hole. In some embodiments, each hole comprises a through hole. In other embodiments, each hole comprises a blind hole. The surveillance robot may also comprise a port spring element that provides a spring force. In embodiments, the spring force provided by the port spring element acts to bias each of the rollers toward the port driven flange of the port driven member. In embodiments, the port spring element comprises a wave spring.

In embodiments, the starboard mating shaft portion of the starboard driven member extends through a lumen defined by the starboard spring element and the port mating shaft portion of the port driven member extends through a lumen defined by the port spring element. In embodiments, the surveillance robot further comprises a starboard pressure plate and a port pressure plate. In embodiments, the starboard mating shaft portion of the starboard driven member extends through a starboard pressure plate opening defined by the starboard pressure plate. In embodiments, the starboard pressure plate is disposed between the starboard spring element and a plurality of rollers. In embodiments, these rollers are at least partially disposed in the apertures defined by the starboard driving flange portion. In embodiments, the port mating shaft portion of the port driven member extends through a port pressure plate opening defined by the port pressure plate. In embodiments, the port pressure plate is disposed between the port spring element and a plurality of rollers. In embodiments, these rollers are at least partially disposed in the apertures defined by the port driving flange portion.

In embodiments, the surveillance robot further comprises a starboard retention ring, a starboard pressure disk, a port retention ring, and a port pressure disk. In embodiments, the starboard retention ring is received in a groove defined by the starboard mating shaft portion of the starboard driven member and the port retention ring is received in a groove defined by the port mating shaft portion of the port driven member. In embodiments, the starboard mating shaft portion of the starboard driven member extends through a starboard pressure disk opening defined by the starboard pressure disk. In embodiments, the starboard pressure disk is disposed between the starboard spring element and the starboard retention ring. In embodiments, the port mating shaft portion of the port driven member extends through a port pressure disk opening defined by the port pressure disk. In embodiments, the port pressure disk is disposed between the port spring element and the port retention ring.

In embodiments, each driven shaft portion includes a thread. In embodiments, a nut may threadingly engage the thread on each driven shaft portion. In embodiments, a wheel may be fixed to each driven shaft portion. In embodiments, a starboard ring panel is disposed between a starboard retaining ring and a starboard pressure disk. In embodiments, a port ring panel is disposed between a port retaining ring and a port pressure disk. In embodiments, each spring element defines a spring lumen.

A feature and benefit of embodiments is a highly consistent torque limiting function, both between different assemblies and through time on a given assembly.

A feature and benefit of embodiments is a torque limiting function that remains consistent while being exposed to contaminants such as water, grease and oil. A related feature and benefit of embodiments is a design that allows portions of the drivetrain to be lubricated without concern that lubricant will interfere with the operation of the torque limiting mechanism.

The above summary is not intended to describe each illustrated embodiment or every implementation of the present disclosure.

DESCRIPTION OF THE DRAWINGS

The drawings included in the present application are incorporated into, and form part of, the specification. They illustrate embodiments of the present disclosure and, along with the description, serve to explain the principles of the disclosure. The drawings are only illustrative of certain embodiments and do not limit the disclosure.

FIG. 1 is a top, front, left perspective view of a throwable robot in accordance with the detailed description.

FIG. 2 is a top, rear, right perspective view of a throwable robot in accordance with the detailed description.

FIG. 3 is a top, rear, left perspective view of a throwable robot in accordance with the detailed description.

FIG. 4 is a top, front, right perspective view of a throwable robot in accordance with the detailed description.

FIG. 5 is an exploded perspective view showing a wheel and a torque limiting assembly/mechanism in accordance with the detailed description.

FIG. 6 is an exploded perspective view showing a wheel and a torque limiting assembly/mechanism in accordance with the detailed description.

FIG. 7 is an exploded perspective view showing a torque limiting assembly/mechanism in accordance with the detailed description.

FIG. 8 is an exploded perspective view showing a torque limiting assembly/mechanism in accordance with the detailed description.

FIG. 9 is a perspective view showing a portion of a throwable robot. In the embodiment of FIG. 9, the wheels and a cover have been removed from the throwable robot for purposes of illustration.

FIG. 10 is a cross-sectional view illustrating a torque limiting assembly/mechanism in accordance with the detailed description.

FIG. 11 is an exploded perspective view showing a torque limiting assembly/mechanism in accordance with the detailed description.

FIG. 12A is an exploded perspective view of a throwable robot in accordance with the detailed description.

FIG. 12B is an enlarged perspective view further illustrating a torque limiting assembly/mechanism shown in FIG. 12A.

FIG. 12C is an enlarged perspective view further illustrating a torque limiting assembly/mechanism shown in FIG. 12A.

FIG. 13 is a partially cross-sectioned perspective view further illustrating the torque limiting assembly/mechanism shown in FIG. 12B.

FIG. 14 is an exploded perspective view showing a torque limiting assembly/mechanism in accordance with the detailed description.

FIG. 15 is an exploded perspective view showing a torque limiting assembly/mechanism in accordance with the detailed description.

While the embodiments of the disclosure are amenable to various modifications and alternative forms, specifics thereof have been shown by way of example in the drawings and will be described in detail. It should be understood, however, that the intention is not to limit the disclosure to the particular embodiments described. On the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the disclosure.

DETAILED DESCRIPTION

Referring to FIGS. 1 and 2, in embodiments, a throwable surveillance robot 100 comprises a pair of axially aligned drive wheels 102, each wheel 102 having a maximum diameter. The surveillance robot 100 may have a body 104 comprising a housing 106 extending between the drive wheels 102. In embodiments, the housing 106 is disposed completely within a cylinder defined by the maximum diameters of the drive wheels 102. In embodiments, the housing 106 defines a housing cavity 108 containing a receiver 110, a transmitter 112 and a video camera 114 connected to the transmitter 112. The housing 106 may include a key holding portion 116 defining a key holding slot 118 having a key insertion and withdrawal axis. In embodiments, throwing of the surveillance robot 100 is facilitated by a design providing a total weight of less than six pounds. The pair of axially aligned drive wheels a starboard drive wheel 102 and a port drive wheel 102.

Referring to FIGS. 1 and 12A, in embodiments, the surveillance robot 100 comprises a pair of motors disposed inside the housing cavity 108 defined by the housing 106. In embodiments, the pair of motors comprises a starboard motor 122 and a port motor 122, each motor comprising a motor shaft. A starboard motor gear 124 may be fixed to the motor shaft of the starboard motor 122. The starboard motor gear 124 may comprise a plurality of gear teeth configured to mate with the toothed outer portion 128 of a starboard drive member 126. In embodiments, the starboard drive member 126 comprises a starboard driving flange portion 130 and the toothed outer portion 128. In embodiments, the starboard driving flange portion 130 defines a plurality apertures 132. The apertures 132 may be arranged in a radial pattern extending along a circular path. In embodiments, the starboard driving flange portion 130 of the starboard drive member 126 defines a central opening 166.

Referring to FIGS. 1 and 7-15, in embodiments, the surveillance robot 100 comprises a starboard driven member 138 comprising a mating shaft portion 168 that extends through the central opening 166 defined by the starboard drive member 126. In embodiments, the driven member 138 is positioned so that a driven flange portion 140 of the driven member 138 is disposed opposite the driving flange portion 130 of the starboard drive member 126. In embodiments, the starboard driven flange portion 140 defines a plurality of holes 162, each hole 162 being dimensioned and positioned to temporarily or permanently receive a portion of one of the plurality of rollers 148. In embodiments, each hole 162 is dimensioned and configured such that one of the plurality of rollers 148 cannot pass through the hole 162. In some embodiments, each hole 162 comprises a through hole. In other embodiments, each hole 162 comprises a blind hole. In some embodiments, the rollers 148 comprise a plurality of cylindrical rods. In other embodiments, the rollers 148 comprise a plurality of spherical balls.

Still referring to FIGS. 1 and 7-15, the surveillance robot 100 may also comprise a starboard spring element 158 that provides a spring force. In embodiments, the spring force provided by the starboard spring element 158 acts to bias each of the rollers toward the starboard driven flange portion 140 of the starboard driven member 138. In embodiments, the starboard spring element 158 comprises a wave spring. Wave springs that may be suitable in some applications are disclosed in the following patents, all of which are hereby incorporated by reference: U.S. Pat. Nos. 7,793,923, 6,758,465, 6,669,184, 6,598,406, 6,408,631, 6,068,250, and 5,558,393.

Still referring to FIGS. 1 and 7-15, in embodiments, the surveillance robot 100 comprises a pair of motors disposed inside the housing cavity 108 defined by the housing 106. In embodiments, the pair of motors comprises a port motor 122 and a port motor 122, each motor comprising a motor shaft. A port motor gear 124 may be fixed to the motor shaft of the port motor 122. The port motor gear 124 may comprise a plurality of gear teeth configured to mate with the toothed outer portion 128 of a port drive member 126. In embodiments, the port drive member 126 comprises a port driving flange portion 130 and the toothed outer portion 128. In embodiments, the port driving flange portion 130 defines a plurality apertures 132. The apertures 132 may be arranged in a radial pattern extending along a circular path. In embodiments, the port driving flange portion 130 of the port drive member 126 defines a central opening 166.

Still referring to FIGS. 1 and 7-15, in embodiments, the surveillance robot 100 comprises a port driven member 138 comprising a mating shaft portion 168 that extends through the central opening 166 defined by the port drive member 126. In embodiments, the driven member 138 is positioned so that a driven flange portion 140 of the driven member 138 is disposed opposite the driving flange portion 130 of the port drive member 126. In embodiments, the port driven flange portion 140 defines a plurality of holes 162, each hole 162 being dimensioned and positioned to temporarily or permanently receive a portion of one of the plurality of rollers 148. In embodiments, each hole 162 is dimensioned and configured such that one of the plurality of rollers 148 cannot pass through the hole 162. In some embodiments, each hole 162 comprises a through hole. In other embodiments, each hole 162 comprises a blind hole. The surveillance robot 100 may also comprise a port spring element 158 that provides a spring force. In embodiments, the spring force provided by the port spring element 158 acts to bias each of the rollers toward the port driven flange portion 140 of the port driven member 138. In embodiments, the port spring element 158 comprises a wave spring.

Referring to FIGS. 7-15, in embodiments, the starboard mating shaft portion 168 of the starboard driven member 138 extends through a lumen defined by the starboard spring element 158 and the port mating shaft portion 168 of the port driven member 138 extends through a lumen defined by the port spring element 158. In embodiments, the surveillance robot 100 further comprises a starboard pressure plate 150 and a port pressure plate 150. In embodiments, the starboard mating shaft portion 168 of the starboard driven member 138 extends through a starboard pressure plate opening defined by the starboard pressure plate 150. In embodiments, the starboard pressure plate 150 is disposed between the starboard spring element 158 and a plurality of rollers 148. In embodiments, these rollers are at least partially disposed in the apertures 132 defined by the starboard driving flange portion 130. In embodiments, the port mating shaft portion 168 of the port driven member 138 extends through a port pressure plate opening defined by the port pressure plate 150. In embodiments, the port pressure plate 150 is disposed between the port spring element 158 and a plurality of rollers 148. In embodiments, these rollers are at least partially disposed in the apertures 132 defined by the port driving flange portion 130.

Still referring to FIGS. 7-15, in embodiments, the surveillance robot 100 further comprises a starboard retaining ring 152, a starboard pressure disk 154, a port retaining ring 152, and a port pressure disk 154. In embodiments, the starboard retaining ring 152 is received in a groove defined by the starboard mating shaft portion 168 of the starboard driven member 138 and the port retaining ring 152 is received in a groove defined by the port mating shaft portion 168 of the port driven member 138. In embodiments, the starboard mating shaft portion 168 of the starboard driven member 138 extends through a starboard pressure disk opening defined by the starboard pressure disk 154. In embodiments, the starboard pressure disk 154 is disposed between the starboard spring element 158 and the starboard retaining ring 152. In embodiments, the port mating shaft portion 168 of the port driven member 138 extends through a port pressure disk opening defined by the port pressure disk 154. In embodiments, the port pressure disk 154 is disposed between the port spring element 158 and the port retaining ring 152.

Still referring to FIGS. 7-15, in embodiments, each driven shaft portion 142 includes a thread 144. In embodiments, a nut 146 may threadingly engage the thread on each driven shaft portion 142. In embodiments, a wheel may be fixed to each driven shaft portion 142.

Referring to FIGS. 14-15, in embodiments, a starboard ring panel 156 is disposed between a starboard retaining ring 152 and a starboard pressure disk. In embodiments, a port ring panel 156 is disposed between a port retaining ring 152 and a port pressure disk. In embodiments, each spring element 158 defines a spring lumen 164.

Referring to FIG. 1, a forward direction Z and a rearward direction −Z are illustrated using arrows labeled “Z” and “−Z,” respectively. A port direction X and a starboard direction −X are illustrated using arrows labeled “X” and “−X,” respectively. An upward direction Y and a downward direction −Y are illustrated using arrows labeled “Y” and “−Y,” respectively. The directions illustrated using these arrows may be conceptualized, by way of example and not limitation, from the point of view of a viewer looking through the camera of the robot. The directions illustrated using these arrows may be applied to the apparatus shown and discussed throughout this application. The port direction may also be referred to as the portward direction. In one or more embodiments, the upward direction is generally opposite the downward direction. In one or more embodiments, the upward direction and the downward direction are both generally orthogonal to the ZX plane defined by the forward direction and the starboard direction. In one or more embodiments, the forward direction is generally opposite the rearward direction. In one or more embodiments, the forward direction and the rearward direction are both generally orthogonal to the XY plane defined by the upward direction and the starboard direction. In one or more embodiments, the starboard direction is generally opposite the port direction. In one or more embodiments, the starboard direction and the port direction are both generally orthogonal to the ZY plane defined by the upward direction and the forward direction. Various direction-indicating terms are used herein as a convenient way to discuss the objects shown in the figures. It will be appreciated that many direction indicating terms are related to the instant orientation of the object being described. It will also be appreciated that the objects described herein may assume various orientations without deviating from the spirit and scope of this detailed description. Accordingly, direction-indicating terms such as “upwardly,” “downwardly,” “forwardly,” “backwardly,” “portwardly,” and “starboardly,” should not be interpreted to limit the scope of the invention recited in the attached claims.

In embodiments, a throwable robot with a pair of drive wheels includes a pair of torque limiting mechanisms. In embodiments, the torque limiting mechanisms may prevent external shock loads from damaging a drivetrain. The wheels of a throwable robot may be subject to very high tangential forces upon impact in certain orientations and trajectories, which translates to a high shock load (torque) on the wheel's drivetrain. Isolating internal drive components from these shock loads is important for the longevity of the system, or even to survive just one throw. Therefore, a torque limiting mechanism may be included to allow the wheels to slip under impact conditions. The ideal slip torque is just higher than the peak load applied by the drivetrain in normal operations (with some acceptable margin), which minimizes the shock load transmitted to the drivetrain for a given set of operating conditions.

In embodiments, a torque limiting arrangement, where several hardened steel balls or rods are spring-biased into recesses on an output shaft, while being rotationally coupled by means of a ball cage to an input shaft or hub (the ball cage may be integral to the input shaft, e.g. axial holes through a web in the component). This creates a mechanism that, when a certain torque differential is applied across the input and output components, will disengage them rotationally and allow for relative rotation until the balls re-engage with their detents.

In embodiments, the slip torque may be modified via several parameters, including the radius at which the balls or cylindrical rods are placed (with respect to the main axis), the length of engagement with the detent (which in turn defines the angle of the normal force when disengaging), and the axial load on the balls.

In embodiments, the driving component comprises a drive member with a toothed outer portion, an integral roller cage and a recessed pocket to receive a spring. Roller engagement may be defined by the web thickness in a driving flange portion of the drive member, and the normal force at slip (between the rollers and the driven flange, which contributes to tangential breakout force and thus slip torque) is controlled by the diameter of the holes defined by the driven flange and their relationship to roller diameter and engagement depth. In embodiments, each hole is dimensioned and positioned to temporarily or permanently receive a portion of one of the plurality of rollers. In embodiments, each hole is dimensioned and configured such that one of the plurality of rollers cannot pass through the hole. In embodiments, the design is such that, when the clutch is engaged and in the absence of a torque on the assembly, the balls have some small clearance and are free to move in their pockets. In embodiments, pre-loaded rollers may be utilized.

In embodiments, the torque limiting mechanism includes a retaining ring that axial constrains an assembly including the spring element. In embodiments, the spring element may comprise a multi-turn wave spring with shim ends that allow the spring itself to contact the rollers (as opposed to an intermediate flat washer or other component). In embodiments, the wave spring is flexible and conforms somewhat to the rollers. In embodiments, the torque limiting mechanism includes a shim washer located between the retaining ring and spring and the thickness of the shim washer may be used to adjust the spring preload and therefore the slip torque. In embodiments, the torque limiting mechanism includes a drive face width substantially larger than the web thickness (4 mm vs. 1.1 mm for example), allowing for a compact and weight-saving design that still stands up to the applied loading.

In embodiments, a torque limiting mechanism comprises a plurality of evenly-spaced rollers and holes, the benefits of which may be that design, drafting, and machining are relatively simple, and that a consistent slip torque is provided at any given relative position, of which there will always be an equal amount to the number of rollers used.

In embodiments, a torque limiting mechanism comprises a plurality of unevenly-spaced rollers and holes, which results in fewer than the full set of rollers being engaged in corresponding holes in some positions, allowing fewer roller receiving positions than there are rollers to exhibit the full slip torque (though as a result, more detent positions will exist throughout the rotation that exhibit a lower slip torque). The result is that that except in specific clocking angles between the input and output components where all rollers are engaged with their respective holes, the slip torque will be lower than in the fully-engaged configuration. This embodiment may have the benefit of providing for a longer “throw” in a relatively low-torque condition (compared to the torque when all rollers are fully engaged), substantially reducing the amplitude of subsequent torque pulses applied as the rollers go into and out of engagement with the holes. This may have the effect of increasing fatigue life of the system, if typical slip events cause larger displacements than the spacing between rollers in a similar evenly-spaced design. An example of this second embodiment would be to have six rollers, alternately spaced at 50° and 70° from the previous roller. Upon slipping from the initial position, the two members would rotate 50° before three rollers re-engage with their holes, while the other three rollers are 20° “out of phase” with the nearest holes. The slip torque then would be roughly half of the fully-engaged slip torque. Upon slipping again, another 20° rotation would occur, resulting in the other three rollers engaging and again producing approximately half the fully-engaged slip torque. Finally, a third slip would produce another 50° of rotation, and the entire assembly would have rotated 120° total, resulting in full ball engagement. Notably, in this scenario, three slip events take place to traverse that 120°, vs. the two events that would occur if the rollers were spaced at even 60° intervals. In embodiments, this may be extended to a repeating pattern of 50-70-60 degrees or to other patterns. In principle, this practice may be extended such that only a single relative position between the input and output shafts will produce more than one engaged ball at a time, though in practice this may be difficult to achieve because certain rollers may be very nearly in-phase and even beginning to engage with the next detent in some positions.

In embodiments the robot wheels are less than 6 inches in diameter. In embodiments, less than 5 inches. In embodiments, less than 4 inches. In embodiments, the robot weighs less than 5 pounds.

A feature and benefit of embodiments is a highly consistent torque limiting function, both between different assemblies and through time on a given assembly.

A feature and benefit of embodiments is a torque limiting function that remains consistent while being exposed to contaminants such as water, grease and oil. A related feature and benefit of embodiments is a design that allows portions of the drivetrain to be lubricated without concern that lubricant will interfere with the operation of the torque limiting mechanism.

In embodiments, each drive wheel includes grit fixed to selected portions thereof or the entire drive wheel. In embodiments, an adhesive-backed sheet embedded with abrasive grit (such as an anti-slip tape material) may be cut into a suitable shape, by die cutting or laser cutting or similar, and applied to the tractive surface of the wheel. In embodiments, an edge sealer, comprising, for example, an elastomeric sealant, may be applied around the exposed edges of the applied tape, helping extend longevity in wet conditions. In embodiments, each drive wheel comprises a thermoplastic elastomer, such as a polyurethane, the tractive surface of which is heated and simultaneously pressed against a layer of loose abrasive grit, thereby embedding the grit in the surface of the wheel once cooled. In the embodiments discussed above, a hard abrasive material such as aluminum oxide or silicon carbide may be fixed to the drive wheels and provide longevity and effectiveness on harder surfaces. In embodiments, larger grits (in the range of 8-24 mesh) are used for embedding because they expose more of the grit particle geometry while still significantly embedding into the substrate.

The following United States patents are hereby incorporated by reference herein: U.S. patent Ser. No. 10/046,819, U.S. Pat. Nos. 9,061,544, 6,548,982, 6,502,657, 637,217, and 626,577. Components illustrated in such patents may be utilized with embodiments herein. Incorporation by reference is discussed, for example, in MPEP section 2163.07(B).

The patents and other references mentioned above in all sections of this application are herein incorporated by reference in their entirety for all purposes.

All of the features disclosed in this specification (including the references incorporated by reference, including any accompanying claims, abstract and drawings), and/or all of the steps of any method or process so disclosed, may be combined in any combination, except combinations where at least some of such features and/or steps are mutually exclusive.

Each feature disclosed in this specification (including references incorporated by reference, any accompanying claims, abstract and drawings) may be replaced by alternative features serving the same, equivalent or similar purpose, unless expressly stated otherwise. Thus, unless expressly stated otherwise, each feature disclosed is one example only of a generic series of equivalent or similar features.

The invention is not restricted to the details of the foregoing embodiment(s). The invention extends to any novel one, or any novel combination, of the features disclosed in this specification (including any incorporated by reference references, any accompanying claims, abstract and drawings), or to any novel one, or any novel combination, of the steps of any method or process so disclosed The above references in all sections of this application are herein incorporated by references in their entirety for all purposes.

Although specific examples have been illustrated and described herein, it will be appreciated by those of ordinary skill in the art that any arrangement calculated to achieve the same purpose could be substituted for the specific examples shown. This application is intended to cover adaptations or variations of the present subject matter. Therefore, it is intended that the invention be defined by the attached claims and their legal equivalents, as well as the following illustrative aspects. The above described aspects embodiments of the invention are merely descriptive of its principles and are not to be considered limiting. Further modifications of the invention herein disclosed will occur to those skilled in the respective arts and all such modifications are deemed to be within the scope of the invention. 

What is claimed is:
 1. A wheeled throwable surveillance robot weighing less than six pounds comprising: a housing rotatably supporting at least one drive wheel; a motor supported by the housing and operatively coupled to the at least one drive wheel for selectively rotating the at least one drive wheel; and a torque limiting mechanism operatively coupled between the motor and the at least one drive wheel, the torque limiting mechanism including a drive member and a driven member disposed along a common rotational axis and urged together by a spring bias, the torque limiting mechanism further comprising a plurality of cylindrical rods or a plurality of spherical balls disposed between the drive member and the driven member, the plurality of cylindrical rods or plurality of spherical balls being disposed in a radial pattern extending along a circular path; the torque limiting mechanism allowing relative rotation between the drive member and the driven member when a torque differential is applied across the drive member and the driven member is equal to or greater than a predetermined value.
 2. The surveillance robot of claim 1 wherein the motor comprises a motor shaft, and a motor gear is fixed to the motor shaft, and wherein the drive member is configured as a gear with external teeth connecting to a gear mounted on a shaft of the motor.
 3. The surveillance robot of claim 2, wherein the drive member has a plurality of recesses for receiving the plurality of cylindrical rod or plurality of spherical balls and wherein when the predetermined value is exceeded, the plurality of cylindrical rods or the plurality of spherical balls are released from the plurality of recesses.
 4. The surveillance robot of claim 1, wherein the drive member defining a central opening, the driven member comprising a mating shaft portion extending through the central opening defined by the drive member.
 5. The surveillance robot of claim 4 wherein the driven member comprises a driven flange portion, the driven flange portion of the driven member being disposed opposite a driving flange portion of the drive member, the driven flange portion defining a plurality of holes, each hole being dimensioned and positioned to temporarily or permanently partially receive one of the plurality of cylindrical rods or the plurality of spherical balls.
 6. The surveillance robot of claim 5 wherein the one of the plurality of cylindrical rods or the plurality of spherical balls comprises the plurality of cylindrical rods, and wherein each of the plurality of cylindrical rods is partially received in one of the plurality of apertures defined by the drive member.
 7. The surveillance robot of claim 5 wherein each of the plurality of holes defined by the driven flange portion comprise through holes.
 8. The surveillance robot of claim 5 wherein each of the plurality of holes defined by the driven flange portion is configured as a blind hole.
 9. The surveillance robot of claim 5 wherein the torque limiting mechanism comprises a spring element providing a spring force, the spring force acting to bias each of the plurality of cylindrical rods or each of the plurality of spherical balls toward the driven flange portion of the driven member.
 10. The surveillance robot of claim 9 wherein the spring element comprises one or more wave springs.
 11. A wheeled robot comprising: a pair of drive wheels, each wheel having a maximum diameter; a housing extending between the wheels; a pair of motors supported by the housing, each motor being operatively coupled to one of the drive wheels; a torque limiting mechanism operatively coupled between each motor and the corresponding drive wheel, each torque limiting mechanism including a drive member and a driven member disposed along a common rotational axis, each drive member defining a central opening, the corresponding driven member comprising a mating shaft portion extending through the central opening defined by the drive member; each torque limiting mechanism further comprising a plurality of cylindrical rods or a plurality of spherical balls disposed between the drive member and the driven member, the plurality of cylindrical rods or the plurality of spherical balls being disposed in a radial pattern extending along a circular path encircling the central opening defined by the drive member; each torque limiting mechanism allowing relative rotation between the drive member and the driven member when a torque differential is applied across the drive member and the driven member is equal to or greater than a predetermined value.
 12. The wheeled robot of claim 11 wherein each motor comprises a motor shaft, and a motor gear fixed to the motor shaft of the motor, the motor gear comprises a plurality of gear teeth.
 13. The wheeled robot of claim 12 wherein each drive member comprises a toothed outer portion, the toothed outer portion of the drive member engaging the gear teeth of the motor gear, the drive member comprising a driving flange portion, the driving flange portion defining a plurality apertures, the apertures being arranged in a radial pattern extending along a circular path, the circular path encircling the central opening.
 14. The wheeled robot of claim 13 wherein each driven member comprises a driven flange portion, the driven flange portion of the driven member being disposed opposite the driving flange of the drive member, the driven flange portion defining a plurality of holes, each hole being dimensioned and positioned to temporarily or permanently receive a second portion of one of the plurality of cylindrical rods.
 15. The wheeled robot of claim 14 wherein a first portion of each cylindrical rod is received in one of the plurality of apertures defined by the drive member.
 16. The wheeled robot of claim 14 wherein the holes defined by the driven flange portion comprise through holes.
 17. The wheeled robot of claim 14 wherein the holes defined by the driven flange portion comprise blind holes.
 18. The wheeled robot of claim 14 wherein the torque limiting mechanism comprises a spring element providing a spring force, the spring force acting to bias each of the cylindrical rods toward the driven flange of the driven member.
 19. The wheeled robot of claim 18 wherein the spring element comprises one or more wave springs.
 20. A wheeled robot comprising: a plurality of wheels including at least one drive wheel, the at least one drive wheel having a maximum diameter; a housing supporting the plurality of wheels and the at least one drive wheel, the housing defining a housing cavity containing a receiver, a transmitter and a video camera connected to the transmitter; a drive member comprising comprising a driving flange portion, the driving flange portion defining a plurality apertures, the apertures being arranged in a radial pattern extending along a circular path, the drive member defining a central opening; a driven member comprising a mating shaft portion extending through the central opening defined by the drive member so that the a driven flange portion of the driven member is disposed opposite the driving flange portion of the drive member, the driven flange portion defining a plurality of holes, each hole being dimensioned and positioned to temporarily or permanently receive a portion of one of a plurality of rollers, each hole being dimensioned and configured such that one of the plurality of rollers cannot pass through the hole; a spring element providing a spring force, the spring force acting to bias each of the rollers toward the driven flange of the driven member; wherein the driven member is operatively connected to the at least one drive wheel. 